DE69418819T3 - rotary encoder - Google Patents

Description

BACKGROUND OF THE INVENTION

FIELD OF THE INVENTION

The This invention relates to a rotary encoder and more particularly on a rotary encoder, which is used to measure a rotational speed, a rotation offset or the like of a rotary object suitable is, so that, if a laser beam or a light beam from a laser diode, an LED or a light emitting diode or the like on a radial diffraction grating one with a rotating object (scale) invaded pane, Diffraction light of a predetermined order through the radial diffraction grating according to the rotational speed or direction of rotation the disc undergoes a phase modulation function or is phase-modulated.

RELATED ART

So far There is a rotary encoder as a meter that provides rotation information such as a rotation amount, a rotation direction, or the like with respect to a rotary object in an NC machine tool or the like with big ones Accuracy below one micrometer, for example. One Such rotary encoder is used in various fields.

Especially is a high precision rotary encoder and high resolution a rotary encoder of the diffractive light sintering system well known that a coherent Light beam like a laser beam or the like in one for a moving Object provided diffraction grating is incident from the diffraction grating generated diffraction light beams of predetermined orders alternately interfere with each other, and the number of light and dark sections the resulting interference fringe is counted, whereby a state of motion like a range of motion, Movement information or the like of the moving object obtained become.

If a high resolution and high precision be achieved by using fine grids (radial lattice), become in such a rotary encoder of the diffraction light interference system of a number of diffraction lights generated by the fine gratings only the diffraction lights of special orders from the optical system extracted, and beam paths are superimposed by suitable optical means, whereby an interference signal is obtained.

at The rotary encoders are generally subject to the following conditions required.

• (1-a) By using a disk (turntable), on the radial grids with small diameters of high density have been recorded, high resolution and low inertia are obtained.
• (1-b) The device is thin overall and small.
• (1-c) The encoder belongs to the unit type, so that a Disc and a detection head and the like can be separated and can be directly mounted on an object to be measured, and if they are mounted, they are easy to handle.

on the other hand the assignee of the present invention already has in the European patent with the publication number 0565056 proposed a linear encoder in which by a scale reflected and diffracted light rays interfere appropriately, causing the entire device is reduced.

One Further state of the art is from the doctoral thesis "Dreigitter Schrittgeber", J. Willhelm, University of Hannover, Known in 1978.

SUMMARY OF THE INVENTION

It is the first object of the present invention to further improve encoders already proposed by the assignee of the invention and to provide a rotary encoder using a fine mesh disk with small diameter and high density diffraction gratings (radial gratings) and in which two diffraction lights of predetermined orders are mutually suitably made to interfere with each other which are obtained when a light beam is irradiated on the fine gratings, thereby making it possible to detect rotational information of a rotating object (a disc) at a high resolution while a small and thin one Form of the entire device is realized. This task be is solved by the device according to claim 1. Advantageous developments are specified in the dependent claims.

The The foregoing and other objects and features of the present invention will become apparent from the following detailed description and the appended claims Reference to the accompanying drawings seen.

BRIEF DESCRIPTION OF THE DRAWING

"Embodiments" according to the 1 to 5 are not covered by the patent claim 1 and the dependent claims. Rather, they merely illustrate comparative examples.

1 shows a perspective view of a main portion of an embodiment 1,

2 shows a perspective view of a main portion of an embodiment 2,

3 shows a perspective view of a main portion of an embodiment 3,

4 shows a perspective view of a main portion of an embodiment 4,

5 shows a perspective view of a main portion of an embodiment 5,

6 shows a perspective view of a main portion of an embodiment 6 of the invention,

7 shows a perspective view of a main portion of an embodiment 7 of the invention,

8th shows a perspective view of a main portion of an embodiment 8 of the invention and

9 shows a perspective view of a main portion of an embodiment 9 of the invention.

DETAILED DESCRIPTION THE PREFERRED EMBODIMENTS

1 is a perspective view of a Hauptab section of an embodiment.

A light beam R emitted by a light-emitting device (light source) 1 such as a laser diode, light emitting diode or the like is converted into parallel light in the drawing by an optical system (not shown) and irradiated to a point P1 on a diffraction grating G1 having a linear grating.

A diffraction light plus first order R ₊₁ and zero order diffraction light R ₀ from a plurality of diffraction gratings diffracted by diffraction grating G1 are allowed to point to points P2a and P2b on a radial diffraction grating G2 on a disk connected to a rotation object (not shown) 4 which rotates around a rotation axis Da as a center of rotation as indicated by an arrow Ya.

A light beam R ₊₁ ^-1 diffracted at a point P2a of the first-order radial diffraction grating G2 is allowed to impinge on a point P3a on a linear diffraction grating G3. A light beam R ₀ ⁺¹ which has been diffracted at a point P 2 b of the first-order radial diffraction grating G 2 may be incident on a point P 3 b on the diffraction grating G 3.

at The diffraction grating G3 are arrangement azimuths of the gratings (arrangement directions the grid) at points P3a and P3b are set to be parallel to a grating array azimuth of the diffraction grating G1. The Arrangement azimuths of the grids of the diffraction gratings G1 and G3 become so adjusted that they parallel to the arrangement azimuth at the irradiation point P2a of the radial diffraction grating G2 are.

The diffraction gratings G1 and G3 according to this Ausführungsbei game are by means of linear grating on the built the same base or board surface. The point P1 and the points P3a, P3b are set to be at different positions on the linear grids on the same board surface.

Since a zero-order diffracted light beam R ₊₁ ^-1 ₀ at the point P3a of the diffraction grating G3 is already at a slight angle to the surface of the disk 4 is emitted at the point P2a of the diffraction grating G2 when it is emitted from the diffraction grating G3, it is also extracted at a certain angle relative to such a disk surface.

A light beam R ₀ ⁺¹ _-1 diffracted in the minus-order direction at the point P3b of the diffraction grating G3 is extracted by the diffraction grating G3 in the direction perpendicular to the disk surface. Thus, in the embodiment, the light rays R ₊₁ ^-1 ₀ and R ₀ ⁺¹ _{-1 are} extracted at an intermediate angle from the diffraction grating G3. The beam paths of the light beams R ₊₁ ^-1 ₀ and R ₀ ⁺¹ _-1 partially overlap and interfere to become a photosensitive device 6 directed.

A sine-wave-like light signal (interference signal) in this case is determined based on the bright and dark portions of an interference pattern from the photosensitive device 6 receive. Rotation information of the disc 4 are generated by using an interference signal from the photosensitive device 6 receive. The photosensitive device 6 is constructed so that a photosensitive surface 6a has an array shape at the same regular pitch as that of diffraction stripes formed on the surface of the photosensitive device.

As a result, the phases of the bright and dark portions of the interference light incident on each rectangular photosensitive device coincide, thus an output of the photosensitive device 6 becomes a sine wave-like signal of two periods when the disk 4 rotates at an angle corresponding to a regular distance of the radial diffraction grating G2.

mit

λ:

Wellenlänge des Lichtstrahls R

d:

Intervall zwischen dem Beugungsgitter G1 (G3) und dem radialen Beugungsgitter G2

R:

Abstand (Radius) zwischen dem Zentrum des radialen Beugungsgitters G2 und dem bestrahlten Punkt P2b

N:

die Anzahl der Gitterlinien bzw. Gitter pro Umfang des radialen Beugungsgitters G2

Since the light beam R is a parallel light beam in the embodiment, the photosensitive surface of the photosensitive device has a rectangular shape whose width is narrower than the width of the interference fringe space and which is arranged in an array form to have a regular pitch P. which is given by the following equation. The photosensitive surfaces of the photosensitive devices are connected in parallel.

With

λ:

Wavelength of the light beam R

d:

Interval between the diffraction grating G1 (G3) and the radial diffraction grating G2

R:

Distance (radius) between the center of the radial diffraction grating G2 and the irradiated point P2b

N:

the number of grid lines or grids per circumference of the radial diffraction grating G2

• (1-1) Das optische System, die photoempfindliche Vorrich tung 6 und dergleichen sind angeordnet, um die Gleichung (1) zu erfüllen. Der regelmäßige Abstand der Interferenzstreifen, die auf der photoempfindlichen Vorrichtung 6 ausgebildet werden, wird dem regelmäßigen Abstand der arrayartigen, photoempfindlichen Oberflächen 6a der photoempfindlichen Vorrichtung 6 angeglichen, wodurch es den Interferenzlichtkomponenten derselben Phase bezogen auf die Zeit erlaubt wird, in den photoelektrischen Umwandlungsbereich einzufallen. Somit wird ein periodisches Signal mit einem guten Signal/Rausch-Verhältnis bzw. S/N-Verhältnis von der photoempfindlichen Vorrichtung erhalten.
• (1-2) Indem die Beugungsgitter G1 und G3 mittels linearer Gitter aufgebaut werden, können sich einfach hergestellt werden.
• (1-3) Der Anordnungsazimut des Beugungsgitters G1 wird parallel zu dem Anordnungsazimut an dem Bestrahlungspunkt P2a des radialen Beugungsgitters G2 angeordnet, wodurch ein Interferenzstreifenmuster des Interferenzsignallichts erzeugt wird.

The embodiment has the following features.

• (1-1) The optical system, the photosensitive device 6 and the like are arranged to satisfy the equation (1). The regular spacing of the interference fringes on the photosensitive device 6 are formed, the regular spacing of the array-like, photosensitive surfaces 6a the photosensitive device 6 whereby the interference light components of the same phase are allowed to be incident on the photoelectric conversion region with respect to time. Thus, a periodic signal having a good signal-to-noise ratio or S / N ratio is obtained from the photosensitive device.
• (1-2) By constructing the diffraction gratings G1 and G3 by means of linear gratings, they can be easily manufactured.
• (1-3) The arrangement azimuth of the diffraction grating G1 is arranged in parallel with the arrangement azimuth at the irradiation point P2a of the radial diffraction grating G2, whereby an interference fringe pattern of the interference signal light is generated.

When the optical system is arranged in the embodiment such that only the Be radiation position P1 of the light beam in the radial direction of the disk 4 during monitoring of the output from the photosensitive device 6 Further, only one mounting angle of the diffraction grating G1 (G3) is adjusted, the maximum contrast can be easily obtained. Thus, a feature is present, so that the assembly and mounting work is easy and the component elements are easy to handle.

2 to 5 each show perspective views of main sections according to the embodiments 2 to 5.

The embodiment 2 according to 2 differs from the embodiment 1 according to 1 in that the arrangement azimuths of the diffraction gratings G1 and G2 are arranged parallel to the arrangement azimuth at the irradiation point P2b of the radial diffraction grating G2, whereby an interference fringe pattern of the interference signal light is generated. The other constructions correspond to those according to 1 ,

The diffraction grating G1 according to the embodiments 1 and 2 is arranged to be parallel to both arrangement azimuths at the irradiation points P2a and P2b on the radial diffraction grating G2 on the rotary disk 4 to be.

The embodiment 3 according to 3 differs from the embodiment 1 according to 1 in that the diffraction grating G1 is arranged to have an angular difference in the opposite direction for both of the arrangement azimuths at the irradiation points P2a and P2b on the radial diffraction grating G2 on the rotary disk, namely almost parallel to the arrangement azimuth of the diffraction grating G2 at the center of the points P2a and P2b. The other constructions correspond to those according to 1 ,

The embodiment 4 according to 4 differs from the embodiment 1 according to 1 in that the photosensitive device 6 from two comb-shaped, photosensitive surfaces 6a and 6b is constructed, which fit together and have the same regular distance as the interference fringe on the surface of the photosensitive device 6 is formed, and that a difference between the two photosensitive surfaces 6a and 6b derived output signals by means of a differential amplification circuit AM is extracted and output. The other structures are similar to the embodiment 1.

• (4-1) Selbst wenn die auf der photoempfindlichen Vorrichtung auftreffende Lichtmenge aufgrund eines Einflusses der Instabilität der Ausgabe der Lichtquelle, eines Befestigungsfehlers des optischen Systems oder dergleichen fluktuiert, wird immer ein Amplitudensignal um 0 als periodisches Signal hergeleitet, so daß kein Fehler auftritt, wenn die periodische Fluktuation auftritt. Folglich kann die Messung stabil durchgeführt werden.
• (4-2) Wenn das Intervall zwischen den Beugungsgittern G2 und G1 verschmälert wird, um die kleine und dünne Größe zu verwirklichen, sind der Strahlengang des von dem Beugungsgitter G3 emittierten Interferenzlichtstrahls und der Strahlengang zum Eingeben des Lichtstrahls von der Lichtquelle zu dem Beugungsgitter G1 nah beieinander oder überlagert. Somit wird zum Beispiel das direkt reflektierte Licht des Lichtstrahls, der von der Lichtquelle in das Beugungsgitter G1 einfällt, mit dem Interferenzsignallicht gemischt. Da jedoch die unnötige Lichtkomponente als DC-Komponente aufgrund der Differenzerfassung durch zwei kammförmige, photoempfindliche Oberflächen gelöscht wird, verschlechtert sich das S/N-Verhältnis nicht.

The embodiment has the following features.

• (4-1) Even when the amount of light incident on the photosensitive device fluctuates due to an influence of the output of the light source, a fixing error of the optical system or the like, an amplitude signal is always derived by 0 as a periodic signal so that no error occurs. when the periodic fluctuation occurs. Consequently, the measurement can be stably performed.
• (4-2) When the interval between the diffraction gratings G2 and G1 is narrowed to realize the small and thin size, the optical path of the interference light beam emitted from the diffraction grating G3 and the optical path for inputting the light beam from the light source to the diffraction grating G1 close to each other or superimposed. Thus, for example, the directly reflected light of the light beam incident from the light source into the diffraction grating G1 is mixed with the interference signal light. However, since the unnecessary light component as the DC component is canceled due to the difference detection by two comb-shaped photosensitive surfaces, the S / N ratio does not deteriorate.

The embodiment 5 according to 5 has a structure such that similar diffraction gratings and photosensitive devices are symmetrical about a beam path Rs of the optical path R from the light-emitting device 1 in the embodiment 4 according to 4 are arranged. Namely, three light beams are irradiated on the diffraction grating G2, whereby interference signals are formed on both sides of the beam path Rs.

The light beam R in the diagram emitted by the light-emitting device 1 is emitted to the point P1 on the diffraction grating G1. The three light beams caused by the light irradiation, zero-order diffracted light R ₀ , first-order diffracted light R _{1 and} first-order diffracted light R _-1 are respectively applied to the points P2a, P2b and P2c on the radial one on the disk 4 recorded grating G2 blasted.

The light beam R ₀ ⁺¹ which has been diffracted at the first-order plus point P2b is irradiated to the point P3b on the diffraction grating G3a. The light beam R ₊₁ ^-1 diffracted at the first-order point P2a is irradiated to the point P3a on the diffraction grating G3a. A light beam R _-1 ⁺¹ diffracted at the first-order plus point P2c is irradiated to a point P3c on the diffraction grating G3b. A light beam R ₀ ^-1 diffracted at the first-order point P2b is irradiated to a point P3d on the diffraction grating G3b.

These electrical periodic signals are sine wave-like signals of two periods when the disk 4 is rotated by an angle corresponding to a regular distance of the radial diffraction grating G2.

Since the interference light signal according to the embodiment is obtained from two positions of the diffraction grating G1 by arranging diffraction gratings G3a and G3b in a manner such that the phases of the grating arrangement between the diffraction gratings G3a and G3b are 1/4 of the distance between (point P3a, P3b ) and (point P3c, point P3d) diverge, as in 5 2, the phases of the light and dark portions of the photosensitive devices can be shown 6a and 6b incident interference lights to be shifted by 90 °. Therefore, there is a feature such that in addition to the rotational speed of the disc 4 the direction of rotation can be assessed.

6 to 9 are perspective views of main portions of the embodiments 6 to 9 according to the invention.

The embodiments 6 to 9 differ from the embodiment 1 according to 1 mainly in that the light beams are incident on the points P3a and P3b of the diffraction grating G3, and the light beam diffracted at the point P3a and the light beam diffracted at the point P3b are extracted to be parallel to each other, and both light beams are superposed to thereby form an interference fringe, and that a photosensitive, single-photosensitive surface device as a photosensitive device 6 is used. The other structures are similar to those of Embodiment 1.

A structure of each embodiment according to 6 to 9 is described below in succession, although parts of them according to the aforementioned embodiments according to 1 to 5 correspond.

In the embodiment 6 according to 6 becomes the light beam R emitted by the light emitting device (light source) 1 such as a laser diode, a light emitting diode or the like, is converted into parallel light by an optical system (not shown) and irradiated to the point P1 on the diffraction grating G1 with the linear grating.

The 1st order diffraction light R ₊₁ and the zero order diffracted light R ₀ of a plurality of diffraction lights diffracted by the diffraction grating G1 are allowed to point to the points P2a and P2b on the radial diffraction grating G2 on the disk 4 which is associated with a rotary object (not shown) which rotates around the rotation axis Da as a center of rotation as indicated by the arrow Ya.

The light beam R ₊₁ ^-1 diffracted at the point P2a of the first-order radial diffraction grating G2 is allowed to impinge on the point P3a on the diffraction grating G3 with the linear grating.

The light beam R ₀ ⁺¹ , which is diffracted at the point P2b of the radial diffraction grating G2 in plus first order, may impinge on the point P3b on the diffraction grating G3. The distances of the diffraction gratings at points P1 and P2 are aligned with each other. The distances of the diffraction gratings at the points P2a and P3b are aligned with each other.

The Diffraction grating G3 is set to provide a suitable angular difference θ between the arrangement azimuths of the gratings of the diffraction grating G3 to the Points P3a and P3b and the arrangement azimuth of the gratings of the diffraction grating To have G1.

An emergent Aszimutvektor the light beam R ₊₁ ^-1 ₀ , which was bent at the point P3a of the diffraction grating G3 in the zero order, coincides with an outgoing azimuth vector of the light beam R ₀ ⁺¹ _-1 at the point P3b of the diffraction grating G3 in minus first Order was bent.

Both light beams are superimposed to thereby interfere with each other. The interference light becomes the photosensitive device 6 directed. The photosensitive device 6 generates a sine wave-like light signal based on the bright and dark portions of the interference pattern generated at that moment. A signal processing circuit (not shown) obtains rotation information of the disk by using the light signal 4 ,

Assuming in the embodiment, the disc rotates 4 now by an angle corresponding to a grating pitch of the radial diffraction grating G2, then the sine wave signal of two periods becomes an electric periodic signal from a photosensitive device 6 derived.

The embodiment has been shown with respect to the case where the reflected diffraction light at the diffraction grating G2 on the disk 4 is used and the diffraction gratings G1 and G3 are arranged on the same side. However, by using the transmission diffraction light from the diffraction grating G2, the diffraction gratings G1 and G3 can be arranged to face both sides of the diffraction grating G2.

The Arrangement azimuths of the diffraction gratings at points P3a and P3b on the diffraction grating G3 and at the point P1 on the diffraction grating G1 become according to the embodiment set to have the appropriate angle θ so that the two superimposed Light rays from the diffraction grating G3 made parallel to each other become and become more uniform Inferential light beam is derived. Consequently, a periodic Signal with a good S / N ratio are obtained from the photosensitive device.

Thus, the rotational information of the disc 4 be detected with high accuracy.

• (6-1) Die Beugungsgitter G1 und G3 können leicht hergestellt werden, weil sie lineare Beugungsgitter sind.
• (6-2) Die Beugungsgitter G1 und G3 können leicht entworfen werden, weil sie lineare Beugungsgitter sind.
• (6-3) Wenn die reflektierten Beugungslichtstrahlen verwendet werden, kann das Gerät ferner dünn gemacht werden, weil die Beugungsgitter G3 und G1 in derselben Ebene angeordnet werden können.
• (6-4) Aus ähnlichen Gründen kann der optische Lesekopf auf einer Seite der Scheibe (ein Aufbau, bei dem die Scheibe sandwichartig umgeben ist, wird nicht verwendet) angeordnet sein, so daß der Kopf einfach montiert werden kann.
• (6-5) Da aus ähnlichen Gründen die Beugungsgitter G3 und G1 auf derselben Unterlage bzw. demselben Brett einstöckig ausgebildet werden können, wird die Anzahl der Teile reduziert, und die Ausrichtung muß bei der Montage nicht justiert werden. Ein stabileres Gerät kann kostengünstig ausgebildet werden.

The embodiment has the following advantages.

• (6-1) The diffraction gratings G1 and G3 can be easily manufactured because they are linear diffraction gratings.
• (6-2) The diffraction gratings G1 and G3 can be easily designed because they are linear diffraction gratings.
• (6-3) Further, when the reflected diffraction light beams are used, the apparatus can be made thin because the diffraction gratings G3 and G1 can be arranged in the same plane.
• (6-4) For similar reasons, the optical pickup may be disposed on one side of the disk (a structure in which the disk is sandwiched is not used), so that the head can be easily mounted.
• (6-5) Since, for similar reasons, the diffraction gratings G3 and G1 can be integrally formed on the same board, the number of parts is reduced and the alignment need not be adjusted during assembly. A more stable device can be formed inexpensively.

The embodiment 7 according to 7 differs from the embodiment 6 according to 6 in that radial diffraction gratings are used as diffraction gratings G1 and G3. The other structures are similar to the embodiment 6.

The light beam R in 7 that of the light-emitting device (light source) 1 such as a laser diode, a light emitting diode, or the like is converted into parallel light by an optical system (not shown) and irradiated to the point P1 on the radial diffraction grating G1. The first-order diffracted light R ₊₁ and the zero-order diffracted light R ₀ of a plurality of diffraction lights diffracted by the radial diffraction grating G 1 are allowed to point to the points P2a and P2b on the radial diffraction grating G 2 on the disk 4 incident with a rotary object (not shown) which rotates about the rotation axis Da as a center of rotation as indicated by the arrow Ya.

The light beam R ₊₁ ^-1 , which is diffracted at the point P2a of the radial diffraction grating G2 in the first order minus, is allowed to impinge on the point P3a on the radial diffraction grating G3. The light beam R ₀ ⁺¹ , which is diffracted at the point P2b on the radial diffraction grating G2 in the first order, may impinge on the point P3b on the radial diffraction grating G3.

The Centers of the radial diffraction gratings G1, G2 and G3 coincide and further, the number N of grid lines or lattices is equalized, if it is calculated in relation to the total amount.

Therefore, an outgoing azimuth vector of the light beam R ₊₁ ^-1 ₀ diffracted at the point P3a of the diffraction grating G3 in niliter order is allowed to fall with an outgoing azimuth vector of the light beam R ₀ ⁺¹ incident on the point P3b of the diffraction grating G3 in FIG minus first order is bent.

Both light beams are superimposed to thereby interfere with each other. The interference light becomes the photosensitive device 6 directed.

The photosensitive device 6 generates a sine wave-like light signal based on the bright and dark portions of an interference pattern generated at that moment. A signal processing circuit (not shown) obtains rotation information of the disc 4 by using the light signal.

If the disc 4 According to the embodiment, by rotating at an angle corresponding to a regular interval of the radial diffraction grating, a sine wave-like signal of two periods from the photosensitive device becomes 6 derived.

• (7-1) Da die Beugungsgitter G3 und G1 mittels derselben radialen Beugungsgitterteile aufgebaut werden können, ist die Anzahl der Arten von Teilen reduziert, und der Aufbau kann vereinfacht werden.
• (7-2) Das Gerät ist unempfindlich gegenüber Anbringfehlern. Selbst wenn nämlich ein Abstand d zwischen dem radialen Beugungsgitter G1 (G3) und der Scheibe 4 (Beugungsgitter G2) wegen einiger Gründe (Anbringfehler, mechanische Positionsabweichung, thermische Expansion, usw.) fluktuiert, sind die Positionen der Punkte P2a, P2b, P3a und P3b lediglich verschoben, und sie arbeiten so, daß eine relative Parallelität der austretende Azimutvektoren von zwei Lichtstrahlen erhalten bleibt, die von den Punkten P3a und P3b auf dem Beugungsgitter G3 emittiert werden. Daher ist das Interferenzlichtsignal nicht gestört und ein stabiles Signal kann erzeugt werden.
• (7-3) Das Gerät ist unempfindlich gegenüber einer Umgebungstemperaturfluktuation. Selbst wenn die Umgebungstemperatur fluktuiert, und die Wellenlänge λ der Lichtquelle fluktuiert, sind die Positionen der Punkte P2a, P2b, P3a und P3b lediglich verschoben, und sie funktionieren so, daß eine relative Parallelität der austretenden Azimutvektoren der zwei Lichtstrahlen erhalten bleibt, die von den Punkten P3a und P3b auf das Beugungsgitter G3 emittiert werden. Daher ist das Interferenzlichtsignal nicht gestört, und ein stabiles Signal kann erzeugt werden.

The embodiment has the following features.

• (7-1) Since the diffraction gratings G3 and G1 can be constructed by the same radial diffraction grating parts, the number of kinds of parts is reduced, and the structure can be simplified.
• (7-2) The device is insensitive to mounting errors. Namely, even if a distance d between the radial diffraction grating G1 (G3) and the disc 4 (Diffraction grating G2) fluctuates due to some reasons (mounting error, mechanical positional deviation, thermal expansion, etc.), the positions of the points P2a, P2b, P3a and P3b are merely shifted, and they operate such that a relative parallelism of the outgoing azimuth vectors of two Light rays are emitted, which are emitted from the points P3a and P3b on the diffraction grating G3. Therefore, the interference light signal is not disturbed and a stable signal can be generated.
• (7-3) The unit is insensitive to ambient temperature fluctuation. Even if the ambient temperature fluctuates and the wavelength λ of the light source fluctuates, the positions of the points P2a, P2b, P3a and P3b are merely shifted, and they function to maintain a relative parallelism of the outgoing azimuth vectors of the two light beams different from the one Points P3a and P3b are emitted to the diffraction grating G3. Therefore, the interference light signal is not disturbed, and a stable signal can be generated.

The embodiment 8 according to 8th differs from the embodiment 6 according to 6 in that the diffraction gratings G1 and G3 with the linear gratings are arranged at an angle θ so as to be parallel to the grating arrangement azimuths at positions P2a and P2b on the radial diffraction grating G2 on the turntable 4 are. The other structures are similar to the embodiment 6.

The light beam R in 8th that of the light-emitting device (light source) 1 such as a laser diode, a light emitting diode or the like is converted into a parallel beam by an optical system (not shown) and irradiated to the point P1 on the diffraction grating G1 with the linear grating.

The first-order diffracted light R _{+ 1} and the zero-order diffracted light R ₀ among a plurality of diffraction lights diffracted by the diffraction grating G1 are allowed to point P2a and P2b on the radial diffraction grating G2 on the disk 4 incident with a rotary object (not shown) which rotates about the rotation axis Da as a center of rotation as indicated by the arrow Ya.

The light beam R ₊₁ ^-1 , which is diffracted at the point P2a of the radial diffraction grating G2 in minus-first order, may impinge on the point P3a on the diffraction grating G3 with the linear grating. The light beam R ₀ ⁺¹ , which is diffracted at the point P2b of the radial diffraction grating G2 in plus first order, may impinge on the point P3b on the diffraction grating G3.

Of the Grid arrangement azimuth of the grating of the radial diffraction grating G2 at the point P2a is parallel to that of the diffraction grating G1 with the linear grid and has the same regular spacing. The grid arrangement azimuth of the radial diffraction grating G2 at the point P2b is parallel to that of the diffraction grating G3 with the linear grating and has the same regular distance.

Since the zeroth-order diffraction light R ₊₁ ^-1 ₀ derived from the point P3a is already in the direction perpendicular to the surface of the disc 4 is therefore also extracted perpendicular to the linear diffraction grating G3. The first-order diffracted light R ₀ ⁺¹ _-1 obtained from the point P3b is emitted in the direction perpendicular to the linear grating G3.

Both light beams are superimposed to thereby interfere with each other. The interference light becomes the photosensitive device 6 directed. The photosensitive device 6 generates a sine wave-like light signal based on the bright and dark portions of the interference pattern at that moment. A signal processing circuit (not shown) obtains rotation information of the disc 4 by using the light signal.

If in the embodiment, the disc 4 is rotated by an angle corresponding to a regular distance of the radial diffraction grating, the sine wave-like signal from two periods of the photosensitive device 6 on a the embodiment 6 obtained in a similar way.

The embodiment 9 according to 9 has a structure such that the optical path Rs of the light beam R from the light emitting device 1 in the embodiment 7 according to 7 is made symmetrical, and similar radial diffraction gratings and photosensitive devices are placed on both sides. That is, three light beams are irradiated on the diffraction grating G2, whereby interference signals are formed on both sides of the optical path Rs.

The light beam R in the diagram emitted by the light-emitting device 1 is emitted to the point P1 on the radial diffraction grating G1. Three light beams generated by the light irradiation, the zero order diffracted light R ₀ , the first order diffracted light R ₊₁ and the first order diffracted light R _-1 are respectively irradiated to the points P2a, P2b and P2c on the radial diffraction grating G2 on the disc 4 is recorded.

The light beam R ₀ ⁺¹ which has been diffracted at the first-order plus point P2b is irradiated to the point P3b on the radial diffraction grating G3a. The light beam R ₊₁ ^-1 diffracted at the first-order point P2a is irradiated to the point P3a on the radial diffraction grating G3a. The light beam R _-1 ⁺¹ diffracted at the first-order plus point P2c is irradiated to the point P3c on the radial diffraction grating G3b. The light beam R ₀ ^-1 diffracted at the first-order point P2b is irradiated to the point P3d on the radial diffraction grating G3b.

The Centers of the radial diffraction gratings G1, G3a and G3b at the points P3a, P3b, P3c and P3d coincide, and the number of grid lines or lattice is aligned when compared to a total perimeter is calculated. Thus, each two light beams on both Pages emitted parallel to each other.

The interference signal lights are made by photosensitive devices 6X and 6y received, so that electrical, periodic signals are generated from them. These electrical periodic signals are sine wave-like signals of two periods when the disc 4 rotates at an angle corresponding to a regular spacing of the radial diffraction grating.

• (9-1) Da die Interferenzsignallichter von zwei Positionen des radialen Beugungsgitters G1 erhalten werden, wie es in 9 gezeigt ist, indem die Gitteranordnungsphasen des radialen Beugungsgitters G1 teilweise verschoben werden und die Phasen zwischen den Punkten P3a und P3b und zwischen den Punkten P3c und P3d um 1/4 des regelmäßigen Abstands verschoben werden, können die Phasen der hellen und dunklen Abschnitte der auf die photoempfindlichen Vorrichtungen 6x und 6y auftreffenden Interferenzlichter um 90° verschoben werden, und die Rotationsrichtung der Scheibe 4 kann auch unterschieden werden.
• (9-2) Indem die Zentren der radialen Beugungsgitter G1 und G2 geeignet verschoben werden, ist es auch möglich, eine Phasendifferenz der hellen und dunklen Abschnitte der Interferenzlichter zu bewirken, die in die photoempfindlichen Vorrichtungen 6X und 6Y einfallen.

The embodiment has the following features.

• (9-1) Since the interference signal lights are obtained from two positions of the radial diffraction grating G1 as shown in FIG 9 is shown by the grating arrangement phases of the radial diffraction grating G1 are partially shifted and the phases between the points P3a and P3b and between the points P3c and P3d by 1/4 of the regular distance are shifted, the phases of the light and dark sections of the on the Photosensitive devices 6x and 6y incident interference lights are shifted by 90 °, and the direction of rotation of the disc 4 can also be distinguished.
• (9-2) By appropriately shifting the centers of the radial diffraction gratings G1 and G2, it is also possible to cause a phase difference of the bright and dark portions of the interference lights formed in the photosensitive devices 6X and 6Y come to mind.

In each of the above embodiments the diffraction order number of the diffraction lights is not on the zeroth, first and minus first order restricted, but all other orders can also be used.

Photosensitive Devices can also be constructed in a way so that two sets of photoelectric device with comb-shaped, matching surfaces are arranged so that they are adjacent, and the phases are mutually shifted, and Signals from four at 90 ° from each other shifted phases are generated.

According to the above embodiments, the disk with a fine mesh with Beu used with small diameter and high density grating gratings (radial gratings), and two diffraction lights of predetermined orders obtained when the light beam is irradiated on the fine gratings mutually interfere with each other. Thus, a rotary encoder can be provided which can detect rotation information of a rotating object (a disk) at a high resolution while realizing the narrow and thin size of the entire apparatus.

• (2-a) Eine hohe Auflösung und eine niedrige Trägheit können durch Verwendung der Scheibe verwirklicht werden, auf der radiale Gitter mit sehr kleinen Durchmessern mit hoher Dichte aufgezeichnet wurden (Gitterabstand: ungefähr 1.6 μm).
• (2-b) Das gesamte Gerät kann in einer dünnen und kleinen Form in der Größenordnung von Millimetern ausgebildet werden.
• (2-c) Das Gerät gehört zu der Einheiten-Bauart, so daß die Scheibe und der Erfassungskopf separat direkt in einem zu vermessenden Gerät montiert werden können. Wenn sie montiert sind, können sie einfach gehandhabt werden.
• (2-d) Der Aufbau ist sehr einfach und die Montagejustierung ist auch einfach.
• (2-e) Wenn die Beugungsgitter zum Teilen und Überlagern der Lichtstrahlen denselben regelmäßigen Abstand wie die Ausführungsbeispiele haben, kann das Gerät als ein Linearkodierer angewendet werden, der die linearen Skalen mit den linearen Beugungsgitter mit demselben regelmäßigen Abstand lesen kann.

Each of the above embodiments has the following features.

• (2-a) High resolution and low inertia can be realized by using the disk on which radial grids with very small diameters of high density have been recorded (lattice spacing: about 1.6 μm).
• (2-b) The entire apparatus can be formed in a thin and small form on the order of millimeters.
• (2-c) The unit belongs to the unit type, so that the disc and the detection head can be separately mounted directly in a device to be measured. When assembled, they can be easily handled.
• (2-d) The construction is very simple and the mounting adjustment is also easy.
• (2-e) When the diffraction gratings for dividing and superimposing the light beams have the same regular spacing as the embodiments, the apparatus can be applied as a linear encoder capable of reading the linear scales with the linear diffraction gratings at the same regular interval.

Claims (10)

Device for detecting relative rotational information with an object to be measured with a radial diffraction grating (G2), comprising: a light source ( 1 for emitting a light beam for measurement, a decomposition diffraction grating (G1) for decomposing the light beam for measurement into a plurality of light beams, a mixing diffraction grating (G3) for mixing at least one set of diffraction lights from a plurality of diffraction lights generated when the plurality of light beams are diffracted by the radial grating (G2), whereby at least one interference light beam is formed, and a detection portion (14) 6 ) for detecting the at least one interference light beam and generating a signal relating to the relative rotation information of the object to be measured, wherein the detecting section (16) 6 wherein the at least one of the decomposition diffraction grating (G1), the mixed diffraction grating (G3) and the light receiving area is configured so that phases of interference light components of the at least one interference light beam incident on the light receiving area substantially coincide with each other, the configuration being an arrangement of the grating line array azimuth at least one of the decomposition diffraction grating (G1) and the mixed diffraction grating (G3) with respect to each other and / or with respect to the radial grating (G2), so that the vectors of interference light components emerging from the mixing diffraction grating (G3) are made parallel to each other and deriving a uniform interference light beam which is applied to the detection section (13). 6 ) to be led. device according to claim 1, wherein the mixing diffraction grating (G3) is the diffraction lights from the radial diffraction grating (G2) of a diffraction light plus first Allocate order with a zero-order light coming from the decomposition diffraction grating (G1) are emitted. device according to claim 2, wherein the decomposition diffraction grating (G1) and the Mixed diffraction gratings (G3) are radial diffraction gratings. device according to claim 2, wherein the mixing diffraction grating (G3) has an arrangement azimuth which is parallel to an arrangement azimuth of the radial diffraction grating (G2) is at a landing position of the zeroth-order light, and the decomposition diffraction grating (G1) has an arrangement azimuth, parallel to an array azimuth of the radial diffraction grating (G2) at an incident position of the diffracted light plus first Order is. An apparatus according to claim 1, wherein said mixed diffraction grating (G3) comprises: a first diffraction grating portion (G3a) for mixing said diffraction lights from said first order diffracted light radial diffraction grating (G2) and zero order light emitted from said decomposition diffraction grating (G1) and a second diffraction grating section (G3b) for mixing the diffraction lights from the radial diffraction grating (G2) of a first-order diffracted light with the zeroth-order light emitted from the decomposition diffraction grating (G1), and wherein the detecting section (12) 6 ) a plurality of photosensitive areas ( 6X . 6Y ) for respectively receiving interference light beams emitted from the first and second diffraction grating sections (G3a, G3b), respectively. device according to claim 5, wherein the first and second diffraction grating sections (G3a, G3b) a plurality of diffraction lights to be mixed in parallel Convert lights and emit them each. Apparatus according to claim 5, wherein said detecting section (16) 6 ) Forms signals with two different phases from the interference light beams, each from the photosensitive areas ( 6X . 6Y ) are received. device according to claim 1, wherein the radial diffraction grating (G2) is provided is to be in one piece to be rotated with the object to be measured. device according to claim 8, wherein the radial diffraction grating (G2) is a diffraction grating of the reflection type. device according to claim 9, wherein the decomposition diffraction grating (G1) and the Mixed diffraction grating (G3) provided on the same base become.